DE60307011T2 - Power transmission mechanism and compressor - Google Patents

Description

The The present invention relates to a power transmission device accordingly the generic term of the independent Claim 1 and a compressor using the power transmission device. The compressor contains a positive displacement compressor and a turbo compressor. The positive displacement compressor contains one Reverse processor and a rotary compressor. The inverse processor contains a swash plate, a swash plate, a swash plate, a Crank and a Scotch fork joint compressor.

A conventional power transmission is adapted to a clutchless compressor, as with respect to the Japanese Patent Application Laid-Open No. 2000-87850. The compressor contains one Hub in a housing. The hub is wearing rotating a pulley using a bearing. The casing picks up a wave. The shaft is out with the hub, which is outward the hub protrudes, a coaxially mounted. The wave has one on one Hub attached end.

The Hub has a cover part attached to it using a rivet is attached. The cover has recesses at the peripheral edge. The recesses are on the identical circle around the shaft in an angular Distance arranged. Each of the recesses has a cushion rubber in it, stuck to it. Each end of the recesses has a bore which rotatably receives a ball, of which a part sticking out of the hole.

The Pulley has a side opposite to the cover. The page has a first hole on the identical circle in which the ball is rotatably received. The identical circle has one second bore into which the ball, released from the first hole, falls down.

The outer circumference the pulley has a belt that is put on it. Of the Belt is connected to a crankshaft. When driving the machine the pulley is rotated and power is transmitted to the shaft transfer the cushion rubber, the cover and the hub.

It It is assumed that the clutchless compressor has an abnormality such as an abnormality. Seizure, generates and the load torque over a predetermined value increases. The respective cushion rubbers will be deformed and released from first holes and get into the second Holes. This cuts the transmission from force from the pulley to the shaft, causing the pulley is put into idle.

The conventional Technology has a complicated structure, a large number of components and manufacturing stages and high production costs. Decrease in the conventional technique Wear or Age wear on the cushion rubber the limit of load torque, if the transfer is cut off from the torque toward the compressor.

A power transmission, as shown above, can be found in the prior art document EP 1 179 678 A2 be removed. In particular, the prior art power transmission mechanism transmits power from a motor to the drive shaft of a compressor. A pulley is supported by the compressor and coupled to the engine. A hub is connected to the drive shaft. Rollers are arranged on the pulley. Elastic transmission arms are located between the pulley and the hub. The leading end of each arm is curved and the closest end is coupled to the hub. When the rollers are engaged with the arm, the force is transmitted to the pulley and the hub. Due to the excessive torque, the rollers escape from the corresponding arm so that the power transmission between the pulley and the hub is released. The leading ends of the arms are movable in the radial direction. In particular, when the rollers are disengaged from the respective arms, the continuous ends of the arms move so that the pulley and hub move radially without interference from the arms. The transmission arms are each formed by a leaf spring. Accordingly, each transfer arm has an elastic property.

It is an object of the present invention, a power transmission for one Compressor, as described above, with high reliability and stable power transmission to accomplish.

Corresponding In accordance with the present invention, the target is a power transmission for a compressor with the features of the independent claim 1 solved.

preferred embodiments are in the dependent claims resigned.

Corresponding The present teaching is a power transmission device and a compressor provided, which has a simplified structure for Shorten the production time and to reduce the manufacturing costs.

According to the present teachings, there are provided a power transmission device and a compressor comprising a shaft of a compressor reduce in the axial dimension.

Corresponding The present teaching is a power transmission device and a compressor provided a reduction of the limit prevents a load torque when transmitting the force in the Direction to the compressor is cut off, thus ensuring reliability to increase.

below the present invention will be described by means of preferred embodiments illustrated and explained in conjunction with the accompanying drawings. In the drawings, wherein:

1 Fig. 12 is a schematic view of an air conditioning system according to the first embodiment;

2 a cross-sectional view of a compressor in 1 is;

3 an elevational view of a power transmission device in the 2 is;

4 is a cross section of the power transmission device, along the line IV-IV in the 3 was taken;

5 an elevation view of the power transmission device after switching off is;

6 a plan view of a leaf spring in the 3 is;

7 a partial sectional view of a power transmission device according to the second embodiment;

8th an elevational view, partially broken, of a power transmission device according to the third embodiment;

9 is a sectional view of the power transmission device, along IV-IV in the 8th has been taken;

10 FIG. 2 is a partial sectional view of the power transmission device taken along XX in FIG 8th taken;

11A to 11E Aufrissdarstellungen are that the operation of the power transmission device in 8th after switching off the energy show;

12 an elevational view, partially broken, the power transmission device of 8th after switching off the energy is;

13 FIG. 14 is a graph showing a result where the release torque with respect to the power transmission device in FIG 8th is measured repeatedly; and

14A and 14B are enlarged elevational views of a leaf spring, which is provided according to the fourth embodiment of the power transmission device.

In 1 An air conditioning system includes a refrigeration cycle and its control device. The refrigeration cycle includes a swash plate compressor 100 to densify a vaporized coolant. The refrigeration cycle contains a cooler 111 to liquefy a coolant. The refrigeration cycle contains an evaporator 121 to evaporate a liquified refrigerant.

The compressor 100 contains a pulley 4 for the drive, attached to a pulley 101 an engine 101 coupled using a belt B. The compressor includes downstream an electronic control valve 102 ,

The cooler 111 has a cooling fan 113 , The cooler contains a liquid tank 112 ,

The controller includes an AC computer 131 that by a battery 133 is fed. The AC computer 131 receives information from the sensors S1, S6, S7 and S8. The sensor S1 detects a temperature at the outlet of the evaporator 121 , The sensor S6 detects a temperature of the vehicle interior. The sensor S7 has a Solai radiation sensor. The sensor S8 detects a temperature outside the vehicle. The AC computer 131 controls the electronic control valve 102 ,

The controller includes ECCS (an electronically concentrated engine control system) 132 , The ECCS 132 receives information from the sensors S2, S3, S4 and S5 to the engine 101 to control. The sensor S2 detects the vehicle speed. The sensor S3 detects the opening ratio of an accelerator. The sensor S4 detects the rotational speed of a wheel or an axle. The sensor S5 detects an intake air pressure of the engine 101 ,

In the 2 contains the swash plate compressor 100 a cylinder block 32 , the six cylinder bores 33 around a wave 7 in a housing 1 forms. Each of the cylinder bores 33 takes a cylinder 48 slidable in it. The compressor 100 contains a front housing 34 that is a crank chamber 35 , adjacent to the cylinder block 32 , forms.

The compressor 100 contains a rear housing 36 , which coolant intake chambers 37 and a coolant discharge chamber 38 in connection with the cylinder bores 33 forms. The cylinder bores 33 and coolant suction chambers 37 . 38 are separated from each other by a valve plate 39 separated. The valve plate 39 has inlets 53 and outlets 56 that the cylinder bores and the intake and discharge chambers 37 . 38 between connect. The valve plate 39 has suction plates 54 that the inlets 53 at the cylinder bores 33 cover. The valve plate 39 has has delivery plates 55 that the outlets 56 at the delivery chamber 38 cover.

The crank chamber 35 contains a drive plate 41 on a wave 7 is attached. The crank chamber 35 contains a sleeve 42 , which slidably with the shaft 7 is used. The crank chamber 35 contains a pin 44 swinging with the shaft 7 using pins 43 connected is. The crank chamber 35 contains a swash plate 45 at the outer end of the pin 44 is attached.

The pin 44 connects with an elongated arcuate bore 46 the drive plate 41 , which limits a vibrational motion.

The pistons 48 are with the swash plate 45 using a pair of shoes 49 connected, with the swash plate 45 between the shoes 49 interposed.

The wave 7 is with the pulley 4 connected for rotation. The pulley 4 is rotatable by the bearing 3 on the front housing 34 stored.

The compressor 100 contains an electronic control valve 102 and a return valve 103 in a rear housing 36 , The control valve 102 carries a portion of a compressed refrigerant in the dispensing chamber 38 to the crank chamber 35 through a canal 52 for regulating the pressure in the crank chamber 35 ,

The swash plate 45 becomes at an inclined angle by the differential pressure between a suction chamber 37 and a crank chamber 35 controlled. The change in the angle of the swash plate 45 changes the stroke of each piston 48 , which changes the discharge volume of a coolant.

In the 4 has the clutchless compressor 100 a housing 1 with a hub 2 , At the hub 2 the pulley is kept rotating, the bearing 3 is used. The pulley 4 has the drive plate 5 attached to the end surface using a screw. The drive plate 5 contains cylindrical protrusions 6 other side. The projections 6 are at the identical circle around the shaft 7 arranged at an angular distance. The pulley 4 and the drive plate 5 form a first transmission part or a driven part.

The housing 1 is with the hub 2 coaxial and takes the shaft 7 on, outward from the hub 2 protrudes. The wave 7 has an end on the hub 10 is attached (second transmission part or drive part), wherein a screw 8th and a washer 9 be used. Like in the 3 shown is the hub 10 shaped as a triangle. The hub 10 has pin insertion holes 11 (related to the 4 ), which are on the identical circle around the shaft 7 are arranged around at an angular distance of 120 degrees.

The hub 10 connects to the drive plate 5 , wherein belt-shaped leaf springs or connecting pieces 12A be used of identical shape and extent. The leaf spring 12A is made of a spring made of high carbon steel. The leaf springs 12A are between drive plate 5 and hub 10 arranged and to one to the shaft 7 vertical direction parallel. For example, the leaf springs extend 12A tangential to the hub 10 to the pulley. In the 6 has each of the leaf springs 12A a through hole 14 at one end in the longitudinal direction, to the outer circumference of the pin (projection) 13 that through the insert bore 11 goes through, is introduced. Each of the leaf springs 12A has a second through hole 15 at the other end in the longitudinal direction, with the outer circumference of a projection 6 is rotatably inserted.

Each of the leaf springs 12A has a slot 16 extending longitudinally from one end edge in the direction to the other end and over the first through hole 14 extends. One end of the leaf spring 12A contains a pair of sidepieces 12aa . 12ab which are opposite each other. Each of the side pieces 12aa . 12ab there forms a slot in between 16 and a first through hole 14 , The first through hole 14 is slightly smaller in size than the pen 13 , The insertion of the pen 13 in the first through hole 14 allows the inner circumference of the first through hole 14 , under a spring force of the leaf spring 12A against the outer circumference of the pin 13 to be pressed. This allows the two circumferences to be in close contact with each other without a gap. It is believed that the compressor 100 the self-seizure inside it generates, and that the load torque rises above a predetermined value. The width of the slot 16 is for the pen 13 fixed in the first through hole 14 is fitted to the slot 16 to squeeze and expand to get out of the slot 16 to escape to the outside.

Each of the leaf springs 12A has a slot 18 extending longitudinally from the second throughbore 15 extending in the direction to the other end. The second through hole 15 is slightly smaller in size than the tab 6 , The lead 6 gets into the second through hole 15 pressed before the head of the projection 6 riveted. The pressing allows the inner circumference of the second through-hole 15 , under the elastic force by the leaf spring 12A against the scope of the projection 6 to be pressed so as to eliminate the gap between the two circumferences. Riveting the head of the tab 6 like a flange prevents the leaf spring 12A out of the lead 6 emerges, as in 4 shown.

Next, the operation of the power transmission device will be described. The power of the engine 101 gets on the pulley 4 applied through the belt B. It is assumed that the load torque at the compressor is lower than a predetermined value. The driving force of the engine 101 becomes the hub 10 through the projection 6 , the leaf spring 12A and the pen 13 to the shaft 7 to turn, transmitted. The rotation shaft 7 turns the swash plate 45 to the stroke of the piston 48 to control.

It is believed that seizure inside the compressor 100 causes a load torque above a predetermined value. Each of the pens 13 gets stuck against the section of the slot 16 in close proximity to the tip end of the leaf spring 12A pressed. The section of the slot 16 or the side pieces 12aa . 12ab is pressed in the transverse direction and widened. This allows the pen 13 entering the first through hole 14 is fitted, from the leaf spring 12A through the slot 16 to be disengaged. The disengaged shifts the transmission of power from the pulley 4 to the wave 7 off, thus the pulley 4 to put in idle. The pencil 13 can be replaced by an elastic cylinder that is elastically deformed to pass through the slot 16 pass.

The leaf spring 12A a spring or an elastic material resists temporal change or wear, and the leaf spring 12A is deformed to interrupt transmission of force. This stabilizes the limit value of the load torque, whereby an accurate interruption of the power transmission is achieved.

Specifically, the embodiment is constructed so that the leaf springs 12A of the same shape and dimension around the shaft 7 are arranged symmetrically at a same angular distance. The arrangement reduces the influence on the leaf springs 12A as a result of varying the strength and the dimension, and advantageously facilitating the interruption of the power supply due to the limit of a desired load torque.

Each of the leaf springs 12A that by the pin 13 is disengaged, is about the projection 6 rotatable. A leaf spring 12A hits a neighboring pen 13 to move towards the circumference of the pulley 4 to turn. The leaf spring 12A runs and locks under the centrifugal force (in terms of the 5 ) with the projection-shaped locking part 19 attached to the drive plate 5 is formed. in the state come the hub 10 and pen 13 with the leaf springs 12A not in contact, and no noise occurs.

The power transmission has a simple structure, and the small number of components and Production levels in comparison with those of the prior art. This shortens the production time and reduces the production costs.

Each of the leaf springs 12A in a plate shape is between the drive plate 5 and the hub 10 arranged and to a direction leading to the shaft 7 is right-angled, parallel. Thus, the wave has 7 a smaller dimension in an axial direction, which advantageously facilitates the installation of the clutchless compressor in one position.

When next becomes the second embodiment described. In the respective embodiments are on identical portions to those of the first embodiment, the identical Reference numbers used and overlapping description is omitted.

In 7 the embodiment has projections 20 , which are integral to the surface of the hub 10 Opposite the hub 10 , are formed in place of the pins 13 of the first embodiment. The projections 20 become one end of the leaf springs 12A used. The other end of the leaf springs 12A has tabs 6 which are rotatably inserted therein.

The projections 6 are to the pulley 4 formed in one piece. This further reduces the number of components, which shortens the manufacturing time and reduces the manufacturing cost.

According to the embodiment, the leaf springs 12A between the hub 10 and the pulley 4 used and are moving in a direction of the thickness of the same limited. This requires no riveting of the projections 6 to prevent the leaf springs 12A from the projections 6 stepping out. This further reduces the manufacturing cost.

When next becomes the third embodiment described.

Regarding the 8th , Contain in the embodiment corresponding leaf springs 12B a pair of forked side pieces 12ba . 12bb that are interconnected. Each of the leaf springs 12B has the side pieces 12ba . 12bb on an end side radially the outer circumference of the outer periphery of the projection 6 crimp radially. Each of the Bittfedern 12B has the other end side by pin 13 rotatably mounted. The leaf spring 12B has two plates 12B1 . 12B2 of identical shape and dimension. The plates 12B1 . 12B2 are punched in a mold and stacked on each other in the direction of the thickness. This facilitates punching to improve the workability and resists burr and deformation for enhancing the dimensional accuracy.

The embodiment has a locking part 19 an elastic member as a washer. The locking part 19 is at the outer periphery of the shaft part 10a the hub 10 used concentrically. The locking member has a peripheral edge which is toward the flange 10 the hub 10 is bent. The locking part 19 slidably presses the corresponding leaf springs 21B against the back of the flange 10b the hub 10 for locking.

According to the power transmission, it is assumed that the compressor has a load torque above a certain value. In the 11B . 11C presses and widens on each of the projections 6 the ends of the side pieces 12ba . 12bb on one side of the end of the leaf spring 12B , the case of the leaf spring 12B disengage. The disengaged interrupts the power transmission from the pulley 4 to the hub 10 , In the 11D comes each of the leaf springs 12B a lead 6 which rotates along a revolution T indicated by a dotted line. In the 11E and 12 , the leaf springs 12B rotate in the circulation, they slide on the locking part 19 , The leaf spring 12B is in one area, without the tabs 6 to touch, locked.

According to the embodiment, the leaf springs come 12B from the pulley 4 that disengages after the power transmission is interrupted. In that case, the leaf springs rotate 12B not during maintenance. Thus, the embodiment prevents the encounter of the leaf springs 12B to an operator and a violation of the operator.

The distance between the leaf spring 12B and pulley 4 requires that a width X is larger than a predetermined size, as in FIG 9 Reference is made. Without a device for positioning the leaf springs 12B in an axial direction of the shaft 7 , changes in the dimensions of the components causes a width X that is smaller than a predetermined size. Thus, a clamping piece is needed to between a tip surface of the shaft 7 and the hub 10 to be used for the recruitment. Like the embodiment, the locking member presses 19 the leaf springs 12B against the hub 10 , This assures a width X larger than a predetermined size, which advantageously saves time for adjustment.

Regarding the 13 , Be the relief torque of the leaf spring 12B and the projection 6 is repeated five times. The goal of the test's is an identical leaf spring 12B and an identical lead 6 , That is, after the disengaged from each other, the leaf spring 12B and the lead 6 come the leaf spring 12B and the lead 6 engaged again for the test. As a result, the relief torques are stabilized at about 80 Nm.

When next becomes the fourth embodiment described.

In 14A has a leaf spring 12C an end where both sides project outwards. The leaf spring 12C has at the end side pieces 12Ca . 12cb , The side pieces 12Ca . 12cb are each other with a slot 22 that between the side pieces 12Ca . 12cb located at the end, opposite. The side pieces 12Ca . 12cb are elastically deformable. The slot 22 extends longitudinally from the end edge to the other end of the leaf spring 12C , The hub 10 has locking parts 21 with insertion recesses 23 into the end of the leaf spring 12C is used.

It is assumed that the clutchless compressor has a load torque that is less than a predetermined value. The side pieces 12Ca . 12cb at the end of the leaf spring 12C are retained to insert into the recess 23 of the locking part 21 to fit, as in 14A shown. When a load torque rises above a predetermined value, the end or side pieces become 12Ca . 12cb the leaf spring 12C elastically deformed, wherein the width is reduced. The leaf spring 12C comes from the insertion recess 23 disengaged, causing, as in 14B shown, the power supply is interrupted.

Corresponding The present teaching is a power transmission device with a small number of components and manufacturing steps made. This shortens the production time and reduces the production costs. The Arrangement of a connection reduces a shaft in the axial Direction.

The Connection does not come with the other part of the driven part and the drive part after switching off the power supply in contact, and there is no sound on.

The Invention does not require riveting to prevent the connection emerges from a first or second engagement part. This shortens the production time further and reduces the manufacturing cost.

The Contains connection Plates of identical shape and dimension, what the work ability while of punching and dimensional accuracy. In addition, in comparison with the connection of a single plate that further stabilizes torque, if an excessive torque the power transmission interrupts.

The Connection resists time-related wear or tear, causing the Threshold of load torque stabilized, reducing reliability is improved. The influence on the connection, the change in the strength and the dimension depends is reduced, whereby the Interruption of energy supply due to the limit of a desired Load torque is facilitated, reducing reliability is improved.

Claims (13)

Power transmission device for a compressor ( 100 ), comprising: a driven part ( 4 . 5 ), rotatable by a motor ( 101 ); a drive part ( 10 ), rotatable coaxially with the driven part ( 4 . 5 ) to a wave ( 7 ) of the compressor ( 100 ) for controlling the displacement of the compressor ( 100 ) to turn; and a connector ( 12A . 12B . 12C ), formed as a leaf spring, which the driven part ( 4 . 5 ) and the drive part ( 10 ) in an intersecting direction relative to the drive shaft (FIG. 7 ), whereby the connecting piece ( 12A . 12B . 12C ) of a part of the driven part ( 4 . 5 ) or the drive part ( 10 ) is disengageable, characterized in that the connecting piece ( 12A . 12B . 12C ) has a slot extending in the longitudinal direction thereof. Power transmission device according to claim 1, characterized in that the connecting piece ( 12A . 12B . 12C ) on the other part of the driven part ( 4 . 5 ) or the drive part ( 10 ) is rotatably mounted. Power transmission device according to claim 1 or 2, characterized in that the other part is a locking part ( 19 ), configured to connect to the connector ( 12A . 12B . 12C ) which is disengaged from the one part. Power transmission device according to claim 3, characterized in that the locking part ( 19 ) includes an elastic member slidably engaging the connector ( 12A . 12B . 12C ) presses against the other part. Power transmission device according to at least one of claims 1 to 4, characterized in that the connecting piece ( 12A . 12B . 12C ) is deformable to disengage from the one part. Power transmission device according to at least one of claims 1 to 5, characterized in that the connecting piece ( 12B ) stacked plates ( 12B1 . 12B2 ) of identical shape and dimension. Power transmission device according to at least one of claims 1 to 6, characterized in that the connecting pieces ( 12A . 12B . 12C ) around the shaft ( 7 ) are arranged at equal angular intervals. Power transmission device according to at least one of claims 1 to 7, characterized in that the one part is a first engagement part ( 13 . 20 . 21 ) and the other part ( 10 ) of the driven part ( 4 . 5 ) or the driving part a second engaging part ( 6 ), wherein the connector ( 12A . 12B . 12C ) contains a first hole ( 14 ), used with the first engaging part ( 13 . 20 . 21 ); a guided tour ( 16 ) extending from the first hole ( 14 ) to an end edge of the connecting piece ( 12A . 128 . 12C ) extends; and a second hole ( 15 ), inserted with the second engaging part ( 6 ). Power transmission device according to claim 8, characterized in that the first engagement part ( 21 ) is deformable. Power transmission device according to claim 8, characterized in that the first engagement part ( 20 ) with the one part ( 10 ) and the second engaging part ( 6 ) with the other part ( 4 . 5 ) is integrated. Power transmission device according to claim 8, characterized in that the connecting piece ( 12A . 12B . 12C ) between the driven part ( 4 . 5 ) and the drive part ( 10 ) is used. Power transmission device according to claim 8, characterized in that the first engagement part ( 13 . 20 ) passes through the guide to the connecting piece ( 12A . 12B ) to be disengaged. Compressor for a vehicle with a power transmission device according to at least one of the claims 1 to 12.